Measuring and control system



June 1 1946.

J. D..RYDER ET AL 2,402,210

MEASURING AND CONTROL SYSTEM Filed Aug. 3, 1942 2 Sheets-Sheet 1 FIG. 2

Snnentors AND ANTHONY J. HORNFECK 8 JOHN D. RYDER attorney June 18, 1946. i D, RYDER H L 2,402,210

MEASURING AND CONTROL SYSTEM Filed Aug. 3, 1942 2 Sheets-Sheet 2 3nnentors AND ANTHONY J. HORNFECK 85 JOHN D. RYDER Patented Jane is, 1,945

umrso srA'rss PATENT orr cs I MEASURING AND CONTROL SYSTEM John D. Ryder, Amos, Iowa, and Anthony 1, Bornveland ts, 0h! llllgnors to Bailey Meter Company, a corporation oi Delaware Application sum 3, 1942, sum No. man

i 1 Claims. (Cl. 112-239) This invention relates to a system for measuring and/or controlling the magnitude of a variable, such as temperature, pressure, rate or fluid ilow, position. or displacement, although the variable may be of any chemical, physical, electrical, thermal, or other characteristic. 1

In accordance withour invention variations in I a variable quantity, quality or condition are translated into variations in an electrical effect, and this efi'ect is then amplified solely through electrical means until sumcient power is available for doing useful work, such as moving an indicator or other exhibiting means, or for regulating the rate of application of an agent contributing to the productionor maintenance or the variable.

In devices of the same general type at present known wherein variations in the, variable are translated into variations in an electrical eifect, the necessary amplification is done, at least in part, by mechanical means. There are, therefore, variations in magnitude or the variable translated into variations in an electrical eil'ect, which is then translated into a corresponding mechan ical movement, such as the deflection or a galvanometer, and thence usually the mechanical movement is translated back into an electrical eflect for operating the exhibiting or control device. Because oi the small power available in the first electrical eil'ect, such devices usually op- One object or the invention is to provide apparatus wherein the manifestations of a resistshoe or other sensitive device may be utilized in the control or amplified power to start, stop and reverse a motor, as well as to control the speed oi a motor when it is operating in selected direction oi rotation.

Another object of the invention is to provide for the simultaneous indication of the value of the variable condition with a control of the ma nitude oi the condition.

A further object o! the invention is to provide for control oi the speed and direction of rotation or a reversible electric motor wherein no contacts are required in the system.

,Still another object is to provide a measuring and/or control system which is continuously and instantaneously responsive to the controlled condition.

A further object is to provide a measuring and/or control system reacting preciselyin predetermined manner to-minute changes in the magnitude of a variable.

Still another object is to provide apparatus which is simple and rugged in construction, reliable in operation, and subject to a minimum of maintenance requirement.

In accordance with preferred embodiments of our invention a condition responsive device, such erate on aperiodic or step by step principle. That a as a resistance or impedance value, controls the is to say, upon a change in the variable the exhibiting or control device is not continuously operated in correspondence with such change or changes, but periodically by means of a feeler mechanism an exhibiting or control device is changed an amount corresponding to the amount of change in the variable during succeeding increments 01' time. Such step by step and feeler mechanisms are well known in the art.

It is evident that such devices are necessarily complicated and delicate and do" not correctly exhibit the variable during transient periods.

energlzation of a control or magnetizing winding of a saturable core reactor to eilect correspending changes in the impedance of the ou put winding of the reactor, which in turn deter- 8| mines the electric energy made available through Our invention is particularly concerned with the elimination of all mechanical movements between the sensitive device and the exhibiting or control device, leading to simplification and removal of the usual time delay, so that the device accurately exhibits the magnitude of the variable, even during transient periods. It i evident that many ancillary advantages will follow, among which may be mentioned as obvious the elimination of wear of mechanical parts and elimination of the necessity of periodic. inspection and adJustment to correct for inaccuracies occasioned by mechanical wear.

an energy utilizing device, such as a motor or the like.

For a more complete understanding or our invention reierence should be made to the description which follows and to the drawings in which:

Fig. l diagrammatically illustrates our invention .in connection with the measurement and control of the rate oi. flow of a i'luid passing through a conduit under pressure.

Fig. 2 diagrammatically illustrates the circuit and arrangementof a modification 01' our invention which is adapted to measure and/or control rate of fluid ilow or other variable.

Fig. 3 illustrates a further modification of our invention.

Referring now particularly to Fig. 7 we have therein illustrated our invention arranged to exhibit and to control the rate 01 flow ot a fluid through a conduit I. The exhibiting means is shown as including a movable index 2 which reacoaaio cords the flow rate on a suitably graduated time revoluble chart 3, and further indicates the flow rate by means ofa scale 4. The rate of flow of the fluid through the conduit I is controlled to a desired standard value by the positioning of a flow regulating valve in the conduit l.

The index 2 and control valve 5 are simultaneously positioned by a motor 6, which is illustrated as a capacitor-run alternating current motor having a wound rotor l and stator windings 8 and 9, the latter constituting running coils electrically ninety degrees apart. The capacitorrun motor is provided with a capacitor or condenser ifl, which, when the motor is rotating, is in series "with either the winding 8 or the winding 9, depending upon desired direction of rotation. Such a motor runs as a two-phase alternating current motor, and not only may be reversed as to direction of rotation, but is susceptible of speed control when rotating in either direction. A particular object of our invention is to provide an improved circuit'arrangement, including saturabl core reactors, for controlling the direction and speed of rotation of the motor 5. We have employed ourinventio'n inthe control and operation of capacitor-run motors up to and including one-half horsepower, but this is by no means to be considered a limitation in the size of a motor which may be controlled in accordance with our invention.

' The arrangement in general provides a D.-G. control current for two saturable core "reactors H and 52. These reactors are connected in the motor circuit in such a way thatthe direction of rotation depends on which reactor is being saturated and the speed of the motor depends on the degree of saturation of the reactor. The saturable core reactor H is provided with a D.-C. saturating winding l3 and an A.-C. output winding i4; while the saturable core reactor I2 is provided with a D.-C. saturating winding l5 and with an A.-C. output winding I6. I i

The motor circuit loop comprises (as clearly indicated in Fig. 1) the output windings l4, IS, the motor windings 8 and 9, and the capacitor Ill, The loop is provided with alternating current energy from a source by way of conductors I1 and i8. Direction and speed bf rotation of the motor 6 is determined by the relative saturation of the direct current windings I3 and I5 of the saturable core reactors H and E2. The saturating windings, may, in a condition of equilibrium, be unsaturated, partially saturated, or fully tor winding 8,, and conductor it to the source. At the same time energy passes through the parallel circuit; conductor ll, output winding i6, ca-

pacitor ill, motor winding d, conductor id to the source. Thus the motor windingt will be connected substantially directly across the source,

' 3 ate!) degrees electrical phase angle to winding saturated. So long as the degree of saturationof the windings l3 and i5 is the same, then the motor control loop-is in a steady state or a state of equilibrium or balance, and no rotation of the rotor l occurs. Upon unbalance of the degree of saturation of the windings i3, i5, i. e. with either the saturation of the one'winding bein decreased relative to the other, or with the saturation of the one winding being increased relative to the other, there will result}; rotation of the rotor 1 in predetermined direction and at a speed determined by the unbalance of the output of the saturable core reactors which is determined by the difference in degree of saturation orthe windings l3 and I5. For example, assume a steady state in which the degree of saturation of the windings l3 and I5 is equal, the energization of the windings 8 and 9 is equal and in phase electrically, and the rotor I is not urged to rotation. If the saturation of the winding I3 is increased then alternating current from the source flows over the circuit; conductor ll, output winding l4, mo-

8, the motor it operates as a two-phase motor in predetermined direction, and when current flows directly through winding 9 and byway of ca= pacitor ill through winding 8 the motor operates in reverse direction as a two-phase motor. Thus when the motor is rotating, capacitor it is always in series with either the winding 8 or with the winding 9 and the motor is termed a capacitorrun motor. The direction of unbalance oi the saturating windings i3 and it determines the di: rection of rotation of the motor 6 and the degree of unbalance determines the speed of rotation in that direction.

As previously mentioned, the motor 6 is adapted to position the index 2 as well as the control value 5. The motor isadditionally connected to simultaneously position a contact member 39 along a balancing resistor 20, which will be hereinafter referred to. We have shown the driving con? nections between the motor 6, index 2, valve 5 and contact element l9 schematically, it bein evident that such reduction gears or other mechanical devices as may be found necessary may i ,in one leg of the U-tube, is a float 24 adapted to position (externally of the U-tube chamber) a contact arm 25 along-a resistance 26 forming part of a balanceable electrical bridge network 21 comprising a loop in which the resistance 20 is also included. Upon an unbalanc ofthe bridge 21, I

as for example by movement of the contact arm 25 along the resistance 26, electric amplifying means (for control of the saturating windings I3 and I5) is actuated, to result in movement of arm I9 and rebalancing of the loop 21.

Connected in circuit with the balanceable bridge 21 is the input circuit or an electron discharge device 28 for controlling the motor control tubes 29, 30. The tubes 29, 30 are preferably arranged in circuit to have opposite polarity, that is the anode of the tube 29 is positive during one half cycle and the anode of the tube 30 is positive during the remaining half cycle. Unbalance of the bridge 21 in one sense will then produce a voltage of the same instantaneous polarity as the anode of the tube 29 (for example) eiiecting will effect operation of the motor rotation of the motor 0 in one direction. Un-

balance of the bridge in opposite direction will produce a voltage having the same instantaneous polarity as the anode. of tube 30, and accordingly 9 in opposite direction. I The output circuit of the device 23 is shown as including a source of direct current 3i and a resistance 32. The grid of the device 2! may be biased so that it is non-conducting or it is conducting a predetermined amount. Such direct current as normally flows through the output circult of the device 23 has no efiect upon the potential impressed upon the grids of the tubes 28 and 39 by virtue of a condenser 33. Upon passage of alternating current through the input circuit of the device 23 however, the current in the output circuit of the device becomes pulsating in character which will pass through the condenser 33 and render either the tube 29 or 30 conducting selectively in accordance with the sense of unbalance of the bridge 21.

The tubes 29 and 30 may normally be maintained non-conducting. This is accomplished by connecting the grids through a resistance 34 to a voltage divider 35. To provide a high degree of sensitivity, in some cases it may be preferable .to maintain the tubes 23 and 30 normally conducting, in which case the pulsating current originating due to unbalance of the bridge 21 will selectively render one or the other of the tubes more conducting.

when either the tube 29 or the tube 30 is conducting it completes its output circuit through the secondary ot a transformer 36 and either the saturating winding I 3 or ii. The related winding ll or II thug has impressed upon it a unidirectional pulsating current comprising the half wave of the alternating current which is passed by the related tube 29 or 30. The other saturating winding is adapted to receive (when its tube 29 or 33 is conducting) the other half wave of the alternating current from the transformer 36 as a unidirectional pulsating current. Flow of such pulsating current through the winding l3 or through the winding i5, or through both in varying degree, varies the saturation of the saturable core reactors H and/or l2. For example, the tubes 29, 30 may normally both be non-conducting, in which event current is not normally flowing through the windings i3 or I5. If either the tube 29 or 30 is rendered conducting, then unidirectional pulsating direct current will flow through the related winding I3 or l5 and in amount dependent upon the degree of conductance of the tube. If normally both tubes 29 and 30 are conducting and equally so, then if one of the. tubes 29 or 30 is rendered more conducting, the related winding i3 or i5 passes more current than under the steady condition of balance, and the resulting unbalance of saturation of the reactors and I2 determines the direction and speed of rotation of the motor 6.

In the embodiment shown in Fig. 1 we preferably arrange the tubes 29 and 30 so that they are of opposite polarity. Thus any component of the current in the output circuit of the device 28 is impressed upon the grids of the tubes 29 and 30 through the condenser 33, which inhibits the passage of direct current. It will, therefore, be solely the component Of the current in the output circuit of the device 23 produced by unbalance of the bridge 21,- which will be effective for controlling the grid-cathode potential relationship of the tubes 29 and 39. As the tubes 29 and 30 have opposite polarity the particular tube rendered conducting during each half cycle when the proper anode-cathode potential relationship exists will be determined by the polarity of the bridge output circuit. The particular motor winding 3 or 9 with which the capacitor ill is connected in series upon unbalance of the bridge is selectively determined therefore in dependence upon the direction of unbalance. As heretofore mentioned, operation of the motor G serves to position the index 2, as well as the valve 5, and the balancing resistance arm l9 along the resistance 2G to restore the bridge to balance.

In this particular embodiment of Fig. 1 we indicate an arrangement adapted to desirably con- "of the bridge 21 is such that the bridge is in balance when the contact arm 25 is at a predetermined position along reslstance 26. Obviously this presumes a definite elevation of mercury 23 in the manometer 22 and thereby a definite differential of pressure across the orifice 2| and a corresponding definite rate of fluid flow throu h the conduit I.

If, due to variation in demand, or for some other external reason, the rate of fiow of fluid through the orifice 2| increases or decreases over the optimum value, the resulting movement of the contact arm 25 along the resistance 26 will cause an unbalance of the bridge 21 in one direction or the other, which will result in an actuation of the motor 8 in predetermined direction whereby the index 2 will be moved to indicate the actual higher or lower rate of fluid through the conduit I from the predetermined value to be maintained. Simultaneously the contact arm i9 will be moved in proper direction and amount along the resistance 20 to balance the bridge 21 and stop rotation of the motor 6. At the same time the motor 6 will move the control valve 5 in proper direction to decrease or increase the rate of fluid fiow as may be required to bring the actual rate back to the optimum value. Obviously the control as a whole will tend to maintain a uniform preselected rate 01' fluid'fiow through the conduit i and will record on the chart 3 the actual rate of fluid fiow at all times. It is apparent that the system may be arranged so that the motor 6 positions only the index 2 and the balancing resistance contact l9 and does not simultaneously positionany regulating valve 5. In such a system the rate of fiow of fluid through the conduit l is, of course, allowed to deviate at will without interference from the control system and the electrical system will serve only to continuously recordupon the chart 3 the position of the index 2, which is representative of the actual diilerential pressure across the orifice 2i. Such a system as we have disclosed provides a telemeter whereby the index 2 with its related chart 3 and indicating scale 4, as well a the .motor 6, may be located remotely a considerable .the type 6L6. The source of direct current in Fig. 2 is by way of a gas rectifier tube 5Y3G, indicated as element 31 on the drawings, and supplied from the alternating current source through a, transformer 38.

In the arrangement of Fig. 2 we have not indicated the motivating force for positioning the contact arm 25 along the resistance 25. Ohviously the arm 25 does not need to be positioned responsive to differential pressure or fluid rate of flow as was illustrated in Fig. l, but may be positioned by and in accordance with any desired variable, quantity, quality, condition, position, etc. For example, it may be positioned in accordance with a temperature value or a pressure value. Furthermore, the arrangement, of Fig. 2 may provide a telemeter wherein merely the position of the arm 25 is remotely indicated or recorded by way of the scale 4 or the recording chart 3. Such position might be manually set up on the arm 25, or the arm 25 may follow some position automatically moved or positioned by machine, a gun, a Searchlight, or the like. In Fig. 2 no control provisions have been shown. but obviously these may be along the general lines illustrated in Fig. l and described in connection therewith.

In Fig. 3 we illustrate the same general arrangement of electric circuit for control of the capacitor-run motor 6 as we have shown inFigs. 1 and 2, but additionally we include a feed-back from the motor windings and'capacitor to reduce overtravel and hunting. The conductors 39 and 40 are connected across the motor windings and lead to a transformer 4i'connected across a resistor 42. A common terminal of the secondary of the transformer 4i and of the resistor 42 is connected to the contact arm 25. A slideable contact engaging the resistor 42 leads to the tube 28A. A pair of transformers 43 and '44 are respectively connected across the motor wind ings 8 and 9 and responsive to the current flow therethrough. The output of the transformers 43. 44 is led to a rectifier 45, which feed the tubes 29A and 30A on a feed-back proportional,

in direction and amount to the rate of change of oltage across the motor windings.

The A.-C feed-back through transformer 4! is a portion of the unbalanced bridge voltage of the motor control circuit and is proportional to the speed of the motor. It is connected in series with the input to. grid of the amplifying tube 28A. The phase of this feed-back voltage reverses with reversal of motor rotation and acts to oppose the unbalance voltage from bridge 21 at any instant. C1 and R1 are adjusted so that the feed-back Er is exactly 180 out of phase with the bridge unbalance voltage Eb as shown in Fig. 3 by the and signs.

Another feed-back proportional to rate of change of speed is introduced into the grid circuits of tubes 29A and 30A. This feed-back is in such a direction as to neutralize the inertia of the motor rotor; thus making the motor start and stop in a shorter interval of time, thereby eliminating overtravel and hunting. To explain the operation, assume that the motor is increasing speed in a clockwise direction produced by an increase in excitation of reactor ll caused in turn by an increase in conduction of tube 29A. Under this condition the voltage across winding 8 becomes greater than that across winding 9. This causes a greater voltage to appear across the secondary of transformer 43. Since the secondary voltage across 43 and 44 is rectified by tube 45, the D.-C. voltage across (a), proportional to the voltage across 8, will become greater than the D.-C. voltage across (b), proportional ll actuate said balancing means, saidmotor coin-- to the voltageacross 9. During the time-that speed control.

the change occurs current will flow through the condenser resistance circuit R23-C23 produce a positive voltage drop across R2 and a. negative voltage drop across Ra relative to-the grids of tubes 29A and 30A. This will increase the conduction of tube 29A and decrease that of 30A, thereby still further hastening the change in motor speed. If, the motor is coming to a stop from the clockwise direction the feed-back voltage will reverse polarity and stop the motor more rapidly.

In general, we provide an improved arrangement and electric circuit which is in total selfbalancing'. Preferably we arrange the circuit to control a capacitor-run alternating current mo-' tor for'reversal of direction of rotation and for It will be appreciated that the drawings and description are illustrative only. andnot necessarily limiting in respect to our invention in its broad aspects.

What we claim as new, and desire to secure by Letters Patent of the United States is:

1. A balanceable electric network including a resistance bridge, means responsive to a variable disturbing the balance upon change in magnitude and producing an alternating current potential across points of the bridge of variable phase or polarity relative to a source of alternating current in accordance with the sense of change 'in the magnitude, balancing means in said bridge for nullifying said potential, a capacitor-run alternating current motor mechanically connected to actuate said balancing means, said -motor comprising two field windings and a capacitor connected in a closed circuit, one terminal of a source of supply being permanently connected to the junction of the two windings and means for alternatively associating the other terminal with the opposite end of either winding and its junction with the capacitor, said means comprisinga pair of saturable core reactors each having a winding connected between said other terminal and one of said opposite ends of the motor windings and each having a saturating winding, a pair of electron discharge devices of variable anode current capacity each having its anode energized continuously at a low value through one of said saturating windings from a source of alternating current, means responsive to the phase or polarity of said potential to ren der one or the other of said devices more conductive and the remaining one less conductive whereby one saturating winding saturates its core more and the other oneless and the motor is actuated in a corresponding-direction and at a across points of thebridge of variable phase or' polarity relative to a source of alternating current in'accordance with the sense of change in the' magnitudejbalancing means in said bridge for nullifyin said potential, a capacitor-run alternating current motor mechanically connected to and,

' prising two field windings and a capacitor connected in a closed-circuit, one terminal ot a source of supply, being ermanently connected to the junction of the two windings and means for alternatively associating the other terminal with the opposite end of either winding and its junction with the capacitor, said meanslcomprising a pair of saturable core reactors each having a winding connected betwee said other terminal and one of said opposite ends of the motor windings and each having a, saturating winding, a pair of electron discharge devices of variable anode currentcapacity each having its anode energized continuously at a low value through one ofs'aid saturating windings from a source of al-' ternating current, means responsive to the phase or polarity of said potential to render one or the other of said devices more conductive and the remaining one less conductive whereby one saturating winding saturates its core more and the other one less and the motor is actuated in a corresponding direction and at a speed dependent upon the diiierential of the saturations to balance the network, each of said devices having a control electrode, means normally biasing said electrodes equally, means providing a feedback potential from the motor fields to change said biasing to said capacitor, a balancing means for nullifying said potential positioned by said motor, circuit means providing rectified feedback potentials from the motor field windings, said potentials being proportional to rate of change of motor speed, and means to. introduce said last mentioned potentials into the input circuits of the motor control tubes in such a direction as to substantially neutralize the inertia, of the motor rotor. j

5. Apparatus comprising means responsive to the magnitude of a variable for establishing an A. C. potential of variable phase relative to a increase the difierential of current flow to the anodes of said devices when the motor is operating, and means energized from the motor fields to partially oppose the change in said bridge potential to prevent overrun oi the motor.

3. A control system including in combination,

\ means sensitive to the value of a variable quantity, quality or condition to be controlled, 2. balanceable bridge network arranged to become unbalanced upon change in said value, a capacitorrun alternating current motor having two windings and a capacitor, rotation of said motor occurring in selected direction when current flow is directly through one of said windings and simultaneously through the other of said windings in series with the capacitor, a pair of saturable core reactors each having an output winding connected in circuit with said motor windings and each having a saturating control winding, the relative impedance of said output windings determining the direction of rotation of said mo tor, normally balanced electron tube means sensitive to unbalance of said network connected to regulate the current flow in said saturating windings for obtaining desired directional rotation of the motor, means positioned by said motor upon the network becoming unbalanced for rebalancing the network, and means responsive to the potential across each motor winding to regulate the bias of the tube controlling the saturating winding of the reactor for the other motor wind- 4. Apparatus comprising means responsive to the magnitude of a variable for establishing an A. C. potential of variable phase relative to a source of A. C. in accordance with the sense of change in said magnitude, a pair of thermionic motor control tubes having their anodes energized by A. 0., input circuits for said tubes so connected to said A. C. potential of variable phase that one or the other of said tubes is selectively rendered more conducting in accordance with the phase of said potential, a capacitor-run A. C. motor having two field windings and a capacitor so arranged in circuit that depending upon which tube is rendered more conducting one of the field windings is directly energized while the other field winding is energized through source of A. C. in accordance with the sense of change in said magnitude, a pair of thermionic motor controltubes having their anodes energized by A. 0., input circuits for said tubes so connected to said A. C. potential of variable phase that one or the other of said tubes is selectively rendered more conducting in accordance with the phase of said potential, a capacitor-run A. C. motor having two field windings and a capacitor so arranged in circuit that depending upon which tube is rendered more conducting one of the field windings is directly energized while the other field winding is energized through said capacitor, a balancing means for nullifying said potential positioned by said motor, circuit means providing rectified feedback potentials from the motor field windings, said potentials being proportional to rate of change of motor speed, means to introduce said last mentioned potentials into the input circuits of the motor control tubes in such a direction as to substantially neutralize the inertia of the motor rotor, circuit means establishing an A, C. feedback potential proportional to the speed of the motor, and a circuit for combining the said A. C. feedback potential in opposition to the A. C. potential of variable phase.

6. A balanceable electric network including a resistance bridge, means responsive to a variable disturbing the balance upon change in magnitude and producing an A. C. potential across the bridge of variable phase relative to a source of A. C. in accordance with the sense of change in the magnitude, balancing means in said bridge for nulliiying said potential, 9. capacitor-run alternating current motor mechanically connected to actuate said balancing means, said motor comprising two field windings and a capacitor connected in a closed circuit, one terminal of a source of A. C. supply being permanently connected to the junction of. the two windings and means for differentially associating the other terminal with the opposite ends of the windings and their junction with the capacitor, said means comprising a pair of electron discharge devices of variable anode current capacity each having its anode energized continuously at a low value through one of said field windings from said source of A, 0., means responsive to the phase of said potential to render one or the other of said devices more conductive whereby the motor is actuated in a corresponding direction and at speed dependent upon the differential to balance the network, each of said devices having a control electrode, means normally biasing said electrodes equally, means providing a feedback potential from the motor fields to change said biasing to increase the difierential of current fiow to the anodes of said devices when the motor is operating, and means energized from the motor fields to partially oppose the change in said bridge potential to prevent over-run of the motor.

7. Apparatus comprising means responsive to v the magnitude of a variable for establishing an alternating current potential oi. variable phase or polarity relative to a source of alternatin current in accordance with the sense oi change in said magnitude, an electron discharge device for amplifying the magnitude of said potential,

a pair or vacuum type motor control tubes ad- :lusted for partial conduction, input circuits for said tubes so connected to said device that one or the other of said tubes is selectively rendered more conducting'in accordance with the phase or polarity oithe potential, 9. pair of saturable core reactors each having a saturating winding and an alternating current output winding, each or said tubes individually controlling the degree of saturation 01 one oi said reactors, a capacitorwindings and a capacitor so arranged in circuit that depending upon which reactor saturating winding predominates as to saturation one of the field windings is directly in circuit through the related reactor output winding to the source of alternating current while the other field winding and capacitor'are in series in circuit through a the same reactor output winding to the source oir alternating vcurrent, electric circuit means run alternating current motor having two ileld JOHN D. RYDER. ANTHONY J. HORNFECK. 

